MODULATION OF SOYBEAN AND MAIZE ANTIOXIDANT ACTIVITIES BY CAFFEIC ACID A ND NITRIC OXIDE UNDER SALT STRESS Ashwil Johan Klein A thesis submitted in partial fulfilment of the requirements for the degree of Doctor Philosophiae in the Department of Biotechnology, University of the Western Cape. Supervisor: Prof. Ndomelele Ndiko Ludidi Co-Supervisor: Dr. Marshall Keyster November 2012 i Modulation of soybean and maize antioxidant activities by caffeic acid and nitric oxide under salt stress Ashwil Johan Klein KEYWORDS Nitric oxide Salinity Reactive oxygen species Cell death Antioxidant enzymes Caffeic acid Lipid peroxidation Superoxide Antioxidant gene expression Salt stress tolerance i ABSTRACT Modulation of soybean and maize antioxidant activities by caffeic acid and nitric oxide under salt stress A.J Klein PhD Thesis, Department of Biotechnology, University of the Western Cape This study explores the roles of exogenously applied nitric oxide, exogenously applied caffeic acid and salt stress on the antioxidant system in cereal (exemplified by maize) and legume (using soybean as an example) plants together with their influence on membrane integrity and cell death. This study investigates changes in H O content, root lipid peroxidation, root cell 2 2 death and antioxidant enzymatic activity in maize roots in response to exogenously applied nitric oxide (NO) and salt stress. This part of the study is based on the partially understood interaction between NO and reactive oxygen species (ROS) such as H O and the role of antioxidant enzymes in plant salt stress responses. The 2 2 results show that application of salt (NaCl) results in elevated levels of H O and an 2 2 increase in lipid peroxidation, consequently leading to increased cell death. The study also shows that by regulating the production and detoxification of ROS through modulation of antioxidant enzymatic activities, NO plays a pivotal role in maize responses to salt stress. The study argues for NO as a regulator of redox homeostasis that prevents excessive ROS accumulation during exposure of maize to salinity stress that would otherwise be deleterious to maize. This study extends the role of exogenously applied NO to improve salt stress tolerance in cereals crops (maize) further to its role in enhancing salt stress ii tolerance in legumes. The effect of long-term exposure of soybean to NO and salt stress on root nodule antioxidant activity was investigated to demonstrate the role of NO in salt stress tolerance. The results show that ROS scavenging antioxidative enzymes like SOD, GPX and GR are differentially regulated in response to exogenous application of NO and salt stre ss. It remains to be determined if the NO- induced changes in antioxidant enzyme activity under salt stress are sufficient to efficiently reduce ROS accumulation in soybean root nodules to levels close to those of unstressed soybean root nodules. Furthermore, this study investigates the effect of long-term exposure of soybean to exogenous caffeic acid (CA) and salt stress, on the basis of the established role of CA as an antioxidant and the involvement of antioxidant enzymes in plant salt stress responses. The effect of CA on soybean nodule number, biomass (determined on the basis of nodule dry weight, root dry weight and shoot dry weight), nodule NO content, and nodule cyclic guanosine monophosphate (cGMP) content in response to salt stress was investigated. Additionally, CA-induced changes in nodule ROS content, cell viability, lipid peroxidation and antioxidant enzyme activity as well as some genes that encode antioxidant enzymes were investigated in the presence or absence of salt stress. The study shows that long-term exposure of soybean to salt stress results in reduced biomass associated with accumulation of ROS, elevated levels of lipid peroxidation and elevated levels of cell death. However, exogenously applied CA reversed the negative effects of salt stress on soybean biomass, lipid peroxidation and cell death. CA reduced the salt stress-induced accumulation of ROS by mediating changes in root nodule antioxidant enzyme activity and gene expression. These CA-responsive antioxidant enzymes were found to be superoxide dismutase (SOD), ascorbate peroxidase (APX), glutathione peroxidase (GPX), and iii glutathione reductase (GR), which contributed to the scavenging of ROS in soybean nodules under salt stress. The work reported in Chapter 2 has been published in a peer-reviewed journal [Keyster M, Klein A, Ludidi N (2012) Caspase-like enzymatic activity and the ascorbate-glutathione cycle participate in salt stress tolerance of maize conferred by exogenously applied nitric oxide. Plant Signaling and Behavior 7: 349-360]. My contribution to the published paper was all the work that is presented in Chapter 2, whereas the rest of the work in the paper (which is not included in Chapter 2) was contributed by Dr Marshall Keyster. November 2012 iv AIMS OF THIS STUDY The study aimed at the following: i. Investigating the role of exogenously applied NO in antioxidant enzyme- mediated ROS scavenging in maize under salt stress. ii. Detection of ROS scavenging maize antioxidant enzyme isoforms whose activity is mediated by exogenous NO in response to salt stress. iii. Determining the effect of NO on antioxidant enzymes in soybean root nodules and how this influences soybean responses to salt stress. iv. Investigating the role of exogenously applied CA in modulating the antioxidant system in soybean root nodules during long-term salt stress. v DECLARATION I declare that “Modulation of soybean and maize antioxidant activities by caffeic acid and nitric oxide under salt stress” is my own work, that it has not been submitted for any degree or examination in any other university, and that all the sources I have used or quoted have been indicated and acknowledged by complete references. Ashwil Johan Klein November 2012 Signed ……………………………………………… vi ACKNOWLEDGEMENTS Firstly, I would like to thank my Heavenly Father for giving me the strength, guidance and wisdom to pursue my goals in life. Secondly, I would like to extend a spe cial thanks to my supervisors Prof. Ndiko Ludidi and Dr. Marshall Keyster for providing me with the opportunity and necessary guidance throughout this study. I would like to acknowledge my parents (Charmaine and Deon Klein) and in- laws (Salomo and Sandra Moses), for their endless love, support and patience through all my years of study until now. All the phone calls, text messages and always being there with a word of encouragement in the difficult times. Words cannot express my gratitude. “To my fiancée (Maretina Moses) and daughter (Chloé Avril Klein), thank you for your steadfast patience and support throughout this study. The 2 of you were my true inspiration and motivation for completing this study. I love you to bits”. To my siblings (Ivoidia, Gwendolene, Jacques, Leandra), the Van Wyk family (John, Yolanda, Candice, Jason) and the rest of the Moses family (Cabral, Leoni) thank you for always believing in me and your extra word of encouragement in difficult times. Thanks to my friends (Eben B, Kevin, Jarries, Catz, DJ Linas, Randal) and colleagues especially Dr. Marshall Keyster, Kyle Phillips, Dr. Morne Du Plessis, Dr. Oom Fani Egbichi, for keeping me sane throughout the writing process with all the silly talk. If I did not mention you, believe me you are not forgotten. The rest of the Plant Biotech Research Group (PBRG) past and present thank you very much for humor throughout this study. Last but not least, this work would not have been possible without financial support from The University of the Western Cape (UWC) and the National Research Foundation (NRF, South Africa). Your contribution is highly appreciated. vii LIST OF ABBREVIATIONS ANOVA analysis of variance AO amine oxidase APX ascorbate peroxidase AsA ascorbic acid AtNOA1 Arabidopsis thaliana Nitric Oxide Associated 1 AtNOS1 Arabidopsis thaliana Nitric Oxide Synthase 1 BSA bovine serum albumin CA caffeic acid CAT catalase cGMP cyclic guanosine monophosphate CYP cysteine protease/ cysteine endopeptidase CYPs cysteine proteases/ cysteine endopeptidases DETA Diethylenetriamine DETA/NO 2,2-(hydroxynitrosohydrazono)bisethanimine DHAsA dehydroascorbate DNA deoxyribonucleic acid DHAR dehydroascorbate reductase EDTA ethylenediaminetetraacetic acid GPX glutathione peroxidase GR glutathione reductase GSH reduced glutathione GSSG oxidised glutathione Lb leghaemoglobin MDA malondialdehyde MES 2-(N-Morpholino)ethanesulfonic acid NADPH nicotinamide adenine dinucleotide phosphate NBT nitrotetrazolium blue chloride viii NO nitric oxide NOS nitric oxide synthase NOX NADPH oxidase NR Nitrate reductase OXO oxalate oxidase PAGE Polyacrylamide gel electrophoresis PCD programmed cell death PVP Polyvinylpyrrolidone RNA ribonucleic acid ROS reactive oxygen species SDS sodium dodecyl sulphate SNP sodium nitroprusside SOD superoxide dismutase TBA thiobarbituric acid TCA trichloroacetic acid TEMED N,N,N′,N′-Tetramethylethylenediamine XO Xanthine oxidase XTT 3-bis(2-methoxy-4-nitro-5-sulfophenyl)-2H-tetrazolium-5- carboxyanilide ix
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